Glass panel

ABSTRACT

A glass panel includes a first surface, and a second surface and wherein the first and second surfaces are spaced apart by thickness of the glass panel. A first image is printed on the first surface of the glass panel and a second image is printed on same first surface of the glass panel and at least partially overlapping the first image. The second image printed on the first surface and at least partially overlapping the first image forms at least partially opaque imbedded into the glass panel image that when covered by a fluid becomes transparent to reveal the first image printed on the second surface of the glass panel.

The present application claims priority to US provisional applicationfor patent 61/670,735 filed Jul. 12, 2012.

FIELD

The present glass panels relate to slip-resistant developable imageglass panels.

BACKGROUND

Flooring tiles are commonly made of ceramic, clay, or stone. These tilesoften have a special surface treatment that increases the frictioncoefficient and prevents slippage making movement on the tile safe. Thetiles are also processed to sustain prolonged periods of wear.

Recently, glass panels (tiles) have become popular for differentdecorative applications including large colored panels, colored glasswalls, doors, and floor tiles. It is known to place different images onone or both sides of a glass panel either to limit visual access throughthe glass sheets or implement a desired decorative pattern. However,glass has a low coefficient of friction, particularly when it is wet.

There are two competing requirements presented when glass panels (tiles)are used as a flooring material, namely aesthetic appearance versussafety of the glass floor. Generally, the glass surfaces could havedifferent finishes and images printed on them that would be visuallyattractive. These surfaces, whilst aesthetically very pleasing to theeye of a viewer, could be slippery especially when they become cleanedor contaminated with fluids. In particular ceramic coatings, oftenrequired over plastic coatings on account of their better wearcharacteristics, can be as slippery as bare glass.

Cleaning of both ceramic and glass tiles covered floors requireapplication of a cleaning fluid, which in most of the cases is waterwith a detergent. Application of the cleaning fluid to a tile or paneltemporarily reduces the friction coefficient and in order to avoiddamages to human beings, warning signs are usually temporary placed onsegments of the floor being cleaned. When the cleaning fluid evaporates,the friction coefficient restores it original value and the signs areremoved.

SUMMARY

A glass panel with high slip resistance can be achieved by depositing onthe surface of the glass panel an ink layer and firing the ink such thatglass frit particles present in the ink become fused to each other andto the glass, and non-melting materials present in the ink provide arough surface with specific chemistry, thus changing the frictioncoefficient of the surface. Generally, more than one image could beprinted on the same surface of the glass panel. For example, two imagescould be printed on the same surface of the glass panel. One of theimages could have a pleasing aesthetic appearance and the other imagecould increase the safety of walking/moving on the glass floor. One ofthe images could be a monochrome image and the other one could be acolor image. Alternatively, both images could be color images. Themonochrome image could be just a surface having a type of “etched glass”appearance. One of the images, typically the image printed second, couldat least partially overlap the first image or printed earlier image. Thesecond image could be an opaque image printed by an ink that after beingfired possess a high friction coefficient and supports formation of anon-slip surface.

The first printed image could be a pictorial image creating an aestheticimpression. Alternatively, it could provide certain information thatcould be important to the viewer or observer of the image. Thisinformation could be a warning message regarding the current status ofthe glass panel surface or could be another message. The second image,at least partially overlapping the first image, is a partially opaque oran opaque image obstructing viewing of the first image. The propertiesof the ink used to print the second image could be selected such as tofacilitate changes in opacity of the second image. Changes in theopacity of the second image could support unobstructed or partiallyobstructed observation of the first image. The changes in the opacity ofthe second image could be caused for example, by a fluid placed over thesecond image. The fluid could be e.g. a cleaning fluid, an artisticallyapplied fluid, atmospheric precipitation such as rain, or anaccidentally spilled drink, and the change in the opacity of the secondimage could be a temporary change facilitated by the presence of thefluid. The second image opacity is restored when the fluid is removedfrom the image, for example, by evaporation.

When the fluid is present and the second image becomes at leastpartially transparent, it reveals the overlapped or partially masked bythe second image segments of the first image and facilitates observationof the first image, which could be a pictorial image or just a warningmessage for example, “Caution Wet Floor” or any other message.

Both the first and the second image could be fired and fused into theglass panel surface. Fusion of the image into the glass panel providesthe images and the glass surface with a high friction coefficient andresistance to wear. Whether wet or dry the second image maintains thehigh friction coefficient.

Both the first and the second image are printed images and could beprinted by different printing techniques for example, screen printing orinkjet printing. In the case that the anti-slip ink is printed by inkjetprinting, then the ink thickness can be varied over the area of theprinted image, resulting in increased roughness that can further improvethe macroscopic anti-slip properties. The present document disclosesprinting of images by inkjet printing methods and accordingly disclosesthe inks suitable for printing the first and the second image. Itdiscloses inks that could be fired and fused into the glass panelsurface. Inks that upon firing fuse to the glass surface and form animage possessing high friction coefficient. Such surface, or at leastthe segment of the surface covered by the second image, is inherently ahigh-slip resistant surface. In addition to high friction coefficientthe glass panel surface covered by the second image has high hardnessand excellent wear resistance. Such surface supports safe human beingwalking as well as repositioning of some objects, for example, furniturewithout damaging the surface.

The process for making a slip-resistant fluid developable image glasspanels results in a long lasting, inherently high-slip resistant glasspanel without the need of any post-manufacturing surface modificationstep or additional of slip-resistant material or coatings.

The advantages of the present glass panel coating and production processare significant because it could be safer to walk on glass tiles andwhen the glass cleaning by a cleaning fluid is in progress oroccasionally spilled fluid or oil is on the surface of the glass panel,it will automatically reveal the developable warning message.

The glass panels disclosed could find use in roofing and walls ofresidential and office buildings. The ink printed on the outside surfaceof the glass panels will be nominally opaque in sunny weather, providingrelief from excessive sunlight and heat. In rainy weather the roof andwalls will become more transparent, allowing a greater proportion oflight to enter through the roof.

GLOSSARY

As used in the present disclosure the term “glass panel” means agenerally transparent glass sheet including a first surface, and asecond surface. The first and second surfaces are being spaced apart bythickness of the glass sheet. A glass panel could have images on one orboth of its surfaces. Glass panels of different size and thickness couldbe used as flooring tiles, decorative walls, and roofing material.

DRAWINGS

FIG. 1 is a simplified illustration of a glass panel printing processaccording to an example;

FIG. 2 is a simplified illustration of a glass panel with two imagesprinted on one of its surfaces according to an example;

FIG. 3 is a simplified illustration of a glass panel with two imagesprinted on one of its surfaces and a fluid layer coating one of theimages according to an example;

FIG. 4 is a simplified illustration of a glass panel with two imagesprinted on one of its surfaces and a fluid layer coating one of theimages according to an example;

FIG. 5 is a simplified illustration of a glass panel with two imagesprinted on different surfaces of the glass panel according to anexample;

FIG. 6 is a simplified illustration of decorative glass floor or a walkside with improved slip-resistance and revealed image according to anexample; and

FIGS. 7A and 7B are simplified illustrations of a building with a roofcovered by the present glass panels according to an example.

DESCRIPTION

One problem that is therefore associated with the use of the existingglass panels or tiles is how to maintain their aesthetically verypleasing to the eye of a viewer or observer appearance and reduce thepotential of slippage for a person walking on them and in particular inthe times when the panels become cleaned or a fluid is occasionallyspilled on them. The present glass panel and process of its manufactureas it will be explained below resolve this problem.

FIG. 1 is a simplified illustration of a glass panel printing processaccording to an example. A glass panel 100 is generally transparentglass sheet including a first surface 104, and second surface 108. Thefirst surface 104 and the second surface 108 are being spaced apart bythickness 112 of the glass panel. A first image 116 is printed on firstsurface 104 of the glass panel 100 and a second image 120 is printed onthe same first surface 104 of glass panel 100. Both the first image 116,printed on the surface of the glass panel 100, and the second image 120could be monochrome or color images. Both the first and the secondimages are fired at a temperature of about 500 degrees C. to 700 degreesC. and more typically about 570 degrees C., which is the Tg temperatureof most industrial glasses. As a result of the firing process both firstimage 116 and second image 120 become fused or imbedded into the glasspanel.

FIG. 2 is a simplified illustration of a glass panel with printed on oneof its surfaces two images according to an example. Second image 120 isprinted on surface of the glass panel 100 by an ink that upon firingforms a partially opaque or an opaque image. The partially opaque oropaque image is fused with the glass panel and forms a wear resistantlayer with a high friction coefficient. Second image 120 after beingfired provides the glass panel at least in the image area with non-slipproperties. It is not necessary to fire the first image before printingthe second image.

In one example the first image is printed by screen printing and thesecond image by inkjet printing. In an additional example, both thefirst and the second images could be printed by inkjet printing. Inkjetis a non-contact printing method so the unfired first printed image willnot be damaged by the printing of the second image on top of it. Thefirst printed image only needs to be dried of volatile ink components,and then the second image can be printed on top of the first image. Bothimages can subsequently be fired together in a single heat-treatment.

Since second image 120 is printed on the same surface 104 of glass panel100 as the first image 116 is printed, it is typically printed over atleast a segment of the first image 116 and at least partially obscuresobservation or viewing of first image 116. FIG. 3 is a simplifiedillustration of a glass panel with two images printed on one of itssurfaces and a fluid layer coating one of the images according to anexample. Second image 120 when covered by a fluid layer 300 becomes atleast partially transparent to reveal the first image 116 printed on thesame first surface 104 of the glass panel 100. The fluid could be atransparent fluid such as water, water with a detergent, and othercleaning fluids and sprays suitable for cleaning glass surface. Thefluid could also be an artistically applied fluid, atmosphericprecipitation such as rain, or an accidentally spilled drink or oil, orhydrocarbons, and the change in the opacity of the second image could bea temporary change facilitated by the presence of the fluid.

Both first image 116, printed on the surface of the glass panel, and thesecond image 120 printed on the surface of the glass panel and at leastpartially obscuring the first image could consist of a pictorial imageor textual image. FIG. 4 is a simplified illustration of a glass panel400 with two images printed on one of its surfaces and a fluid layercoating one of the images according to an example. The first image 404is a textual image. The textual image of FIG. 4 provides information onthe status of surface 104 on which the pictorial or textual image isprinted. It this case textual image 404 informs a person that the flooris wet and he or she should be careful when walking on it.

FIG. 5 is a simplified illustration of a glass panel with two imagesprinted on different surfaces of the glass panel according to anexample. Second image 120 is a color image printed on a first surface104 of a glass panel 500. Second image 120 could be fired at atemperature of about 500 degrees C. to 700 degrees C. and moreaccurately about 570 degrees C., which is close to the Tg temperature ofmost industrial glasses. As a result of the firing process second image120 becomes opaque and fused to or imbedded into the glass panel. Image120 forms a wear resistant layer with a high friction coefficient andslip resistant properties.

In some examples first image 116 could be printed on second surface ofglass panel 500 and it is not necessary fired. When second image 120 iscovered by a fluid layer, for example, in course of the glass panelcleaning, the second image becomes at least partially transparent toreveal the first image 116 printed on the second surface 108 of theglass panel 500. Care should be taken when printing images on both sidesof the glass panel, since the first image printed on the second side ofthe glass panel could be a mirror image of the original image.

Both the first and the second image could be printed by screen printingor by inkjet printing or by a combination of both printing methodsdepending on the length of the printing run. For example, the firstimage such as a warning message could be printed by screen printing,where the second image could be a customized image selected according toparticular customer requests and desires.

In some examples, the thickness of the printed anti-slip ink layer couldbe varied. This is easily achieved by digital printing and in particularinkjet printing but much more difficult to do by e.g. screen printing.This “printed texture” provides further roughness to the surface of theprinted ink layer on the sub-millimeter-millimeter-scale, which furtherimproves the anti-slip quality of the layer.

When printed by inkjet printing the first image 116 could be printed byinks that fuse with the glass panel upon firing. Such inks could have aviscosity between 10 and 100 cps at jetting temperature and include anorganic solvent as a vehicle, which is liquid at room temperature and asa binding composition include sub-micron particles of a glass fritcomposed of SiO₂, Bi₂O₃, and B₂O₃. The glass frit particles wouldtypically have an average size between 0.4 and 1.2 microns. The inkwould also include particles of heat resistant inorganic pigments, forexample, such as metal oxides having an average size of less than 1.2microns. Suitable metal oxides could be chromium oxide, copper oxide,titanium oxide, Cu—Cr₂O₃ oxides; titanium dioxide, iron oxide, Nickelantimony titanium yellow rutile, Cobalt, aluminium, blue spinel; andcombinations of two or more of the above pigments. The organic solventcould be for example, PM (propylene glycol mono-methyl ether), DPM(dipropylene glycol mono methyl ether), TPM (tripropylene glycol monomethyl ether), PnB (propylene glycol mono n-butyl ether), DPnB(dipropylene glycol mono butyl ether), TPnB (trisropylene glycol monon-butyl ether), PnP (propylene glycol mono propyl ether), DPnP(dipropylene glycol mono propyl ether), TPnB-H (propylene glycol butylether), PMA (propylene glycol mono-methyl ether acetate). Dowanol DB(Diethylene glycol mono butyl ether) or other ethylene or propyleneglycol ethers or a combination of two or more of the above solvents.

The ink composition could also include a combination of dispersants, oneor more wetting agents and one or more UV-curable agents as well as anumber of photoinitiators or photosensitizers.

Inks for Printing the Anti-Slip or Non-Slip Image

The second image 120 could be printed by inks, the formulation of whichinclude elements supporting the anti-slip ink properties andfacilitating ink transparency when it is covered by a layer oftransparent fluid.

Typically, the anti-slip particles would be made from alumina. Aluminahas a very high hardness (9.0 on Mohs scale). More importantly, it wasunexpectedly discovered that alumina supports better anti-slip propertythan titania, copper chromate, or silicon dioxide usually used inanti-slip coatings. Without being bound by any specific theory it isbelieved that the anti-slip property is at least in part due to thealumina's surface chemistry. For example, high roughness surfaces withdifferent chemistry can instead produce an opposite effect, due to the“Lotus Effect” (The “Lotus Effect” refers to the very high waterrepellence by a highly structured super hydrophobic surface). Anotherreason for selecting alumina is its refractive index (n˜1.760-1.772),which is close to that of the bismuth-based glass frit (n˜1.7). It isbelieved that this is what allows the anti-slip layer to becomenominally or partially transparent when the surface is made wet (i.e. byapplying a liquid).

Alumina (Al₂O₃) Dispersion

Alumina (99.99% purity, nominal particle size 0.3-1.7 micron),commercially available from American Elements, Inc., Los Angeles Calif.90024 USA, was stirred in DPM with Disperbyk-106 to give a slurrycontaining 70% alumina and 2% dispersant. An equal weight of zirconiamilling beads was added and the mixture was stirred vigorously until themeasured particle size decreased from the initial average of 1.7 micronsto an average of 0.74 microns. The milling beads were then removed byfiltration. The alumina dispersion was used in different percentages(21% to 30%) for preparation of the inks possessing anti-slipproperties.

The average particle size of the anti-slip particles could be in therange 0.3-1.5 micron (for inkjet inks), and typically between 0.8 and1.2 microns. For screen printed inks the anti-slip particles could be ofa larger size, for example 10 or 15 micron, or even more. The amount andsize of the anti-slip particles is selected to support a proper balancebetween the settling behavior of the ink, the jettability, theviscosity, and the fired ink layer roughness provided by largeparticles, within the context of the printer being used.

Glass Frit Component

The frit component or components are selected of a durable composition.The anti-slip frit supports high acid-resistance, and because of it issuitable for use as a flooring material that could sustain accidentalacidic spillages (for example, some types of food or drinks) or cleaningby aggressive substances. Such frit properties are not available frommost currently used low Tg frits, e.g. bismuth or zinc-based frits.Those frits have poor acid-resistance and relatively low durability.

One of the properties of the anti-slip or non-slip ink is its excellentscratch-resistance i.e., a fired ink must not be removed from thesubstrate by repeated scratching with a 30N sclerometer. A suitableratio of glass frit to anti-slip particles in the ink was establishedthrough experiment. The mass ratio of glass frit to anti-slip particlesin the ink is 9:5, more generally between 9:4 and 9:6. This proportionof non-fusing material is more than is used in conventional colored inks(i.e. in the form of pigments). The glass frit is usually used as 70%dispersion in different solvents and the proportion of the dispersioncan vary between 40% to 60%. The conventional colored inks requiregloss, but the present anti-slip ink does not require gloss. The higherthe amount of anti-slip particles, the better the anti-slip property,since more particles “float” on the surface, producing submicron-scaleroughness and reducing the gloss. However, too high an anti-slipparticle concentration could result in reduced mechanical strength ofthe fused layer, which of course is not acceptable.

Typically, inkjet inks contain leveling additives rather thananti-sagging additives, on account of the low layer thickness that theyare printed at. The ink for printing the second image is preferably freeof leveling additives, and could contain anti-sagging additives. Thismeans that the anti-slip inks can provide more uneven surfaces andhigher-resolution, thicker textures, then other firable inks.

Below are some examples of the anti-slip ink formulations:

INK EXAMPLES Example 1 Grey-Colored Alumina-Based Anti-Slip Ink

The ink of example 1 was prepared by mixing the following components:

Content in the ink Component formulation Alumina dispersion (asdescribed above): 23%  Glass frit JFC-004 (70% dispersion in DPM with45%  Disperbyk-180): Black pigment JPC-601 (Johnson Matthey dispersion):3% Dowanol DB (solvent) 5% Cyclohexanone (solvent): 4.85%   Laropal A81solution (binder; 20% solution in DPM): 10%  Disperbyk-180 (dispersantand wetting agent): 2% Byk-415 solution (anti-sagging agent; 10%solution 5% in cyclohexanone): Byk-430 solution (anti-sagging agent; 10%solution 2% in cyclohexanone): Byk-341 solution (surface tensionreducer; 0.15%   10% solution in DPM):

After printing and firing the ink on glass, scratch-resistance was foundto be within specifications stated above i.e., fired ink is not removedby repeated scratching with a sclerometer set to 30N.

The ink was printed on glass in a pattern of 10 mm-sized spot with theglass surface coverage of about 40%. Samples with and without lightbackground of a different ink in the unprinted 60% of the glass surfacewere prepared. Spots with and without a texture pattern were printed.The PTV (Pendulum Test Value) characterizing the slip resistance valueof a surface, of wet glass is around 10, and of wet glass printed withsimilar patterns of standard ink such as for example, DIP SPECTRUM™ inkscommercially available from Dip-Tech Ltd., Kfar Saba 44643 Israel is 12.The PTV of the wet samples (average of three samples measurementsaccording to ASTM E303) were measured to be as follows:

“Flat” non-textured spot “Textured” spots Sample design surface (PTV)surface (PTV) No printed background 22.5 24.5 With printed background 2933Remark: ASTM E303-93(2008) Standard. Test Method for Measuring SurfaceFrictional Properties Using the British Pendulum Tester.

Conclusions:

-   -   i) The ink described in Example 1 gives a large increase in PTV        over standard (conventional) inks.    -   ii) Textured printed areas give a better PTV than un-textured        areas.

Example 2 White-Colored Anti-Slip and Picture-Hiding/Revealing Ink

The ink of Example 2 was prepared by mixing the following components:

Content in the ink Ink Formulation Component formulation Aluminadispersion (as described above): 21% Glass frit (70% dispersion in DPMwith Dispersant): 50% Dowanol DB (solvent)  5% Laropal A81 solution(binder; 20% solution in DPM): 10% Disperbyk-106 (dispersant and wettingagent):  1% Byk-415 solution (anti-sagging agent; 10% solution  9% incyclohexanone): Byk-430 solution (anti-sagging agent; 10% solution 3.8% in cyclohexanone): Byk-341 solution (surface tension reducer; 0.2%  10%solution in DPM):

The ink was, printed on glass in a pattern of 10 mm-sized spot with aglass surface coverage of 40%. Spots with “target” and “spider web”textures were printed. The PTV of wet glass is around 10, and of wetglass printed with similar patterns of standard ink (Dip-Tech black ink)is 12. The PTV of the wet samples (average of three samples measurementsaccording to ASTM E303 Standard) were measured to be as follows:

Printed Sample “Textured” surface Design spots (PVT) “Target” 30.5“Spider web” 31.0

Samples were printed which included standard black ink, such as DIPSPECTRUM™ ink commercially available from Dip-Tech Ltd., Kfar Saba 44643Israel covered with ink of Example 2. These samples were light grey inappearance when dry, but became dark grey upon wetting with water, oil,or other liquids. This process was entirely reversible, with the samplebecoming light grey again after frying, and could be carried out formultiple cycles without any evidence of loss of function. Pictures andmessages (as dark grey on light grey) could be created by painting onthe sample with water.

Conclusions:

-   -   i) The ink described gives a large increase in PTV over standard        printing inks.    -   ii) ii) The ink described adequately demonstrates a “picture        hide/reveal” function.

Example 3 Ink with High-Concentration of Black Pigment

The ink of Example 3 was prepared by mixing the following components:

Content in the Ink Formulation Component formulation Glass frit (70%dispersion in DPM with Dispersant)  49% Black pigment JPC-601 (JohnsonMatthey dispersion)  25% Dowanol DB (solvent)  5% Cyclohexanone(solvent)  5% B-66 binder solution (10% solution in DPM)  10%Disperbyk-180 (dispersant and wetting agent) 0.8% Byk-415 solution(anti-sagging agent) 0.6% Propylene glycol diacetate: 4.5% Byk-341solution (surface tension reducer; 0.1% solution in DPM)

The ink was printed on glass in a pattern of 10 mm-sized spot with aglass coverage of 40%. Spots with and without a lower-thickness innerspot (thus creating some texture) were printed. The PTV of wet glass isaround 10. The PTV of the wet samples (average of three samplesmeasurements according to, ASTM E303) were measured to be as follows:

Printed Sample “Flat” non-textured spot “Textured” spots Design surface(PTV) surface (PTV) Round spots 21.6 23.4

Conclusions:

-   -   i) The ink described gives an increase in PTV over standard inks        such as for example, DIP SPECTRUM™ inks commercially available        from Dip-Tech Ltd., Kfar Saba 44643 Israel on account of its        very high pigment content. However, the PTV remains lower than        for alumina-containing inks.    -   ii) Textured printed areas give a better PTV than un-textured        areas.

Example 4 Ink Providing Etch-Effect, High Acid-Resistance Anti-Slip Ink

The combination of index-matching (of frit and alumina) together withthe micro-rough surface, as we know provides efficient scattering oflight. This effect can also be used to produce an “etched glass” effect.It was discovered that the “etched glass” or “frosted glass” effectcould be enhanced by selecting a glass frit that most closely matchesthe refractive index of alumina (within Δn=0.1 or the refractive indexof the alumina). For example such glass frit as JFC-004 commerciallyavailable from Johnson-Matthey Plc., Stoke-on-Trent ST11 9RD UnitedKingdom. The “etched glass” effect is lost when the glass becomes wetand the glass becomes transparent.

The ink of Example 4 was prepared by mixing the following components:

Content in the ink Ink Formulation Component Formulation Aluminadispersion (as described above) 25% Glass frit JFC-004 (as-received 70%dispersion) 45% Laropal A81 solution (binder; 20% solution in DPM) 10%Disperbyk-180 (dispersant and wetting agent)  2% Byk-341 solution(surface tension reducer; 10% 0.1%  solution in DPM) DPM (solvent)17.9% 

The ink was used to create drawdown samples. After drawdown and firingthe ink on glass, scratch resistance was found to be withinspecifications (fired ink could not be removed by repeated scratchingwith a sclerometer set to 30N). The anti-slip quality of the samples wasqualitatively found to be comparable to the other alumina-containinginks.

The qualitative appearance of the samples was almost identical toacid-etched glass samples or sand blasted glass samples. When placedprinted side-down on a surface, it appeared almost as clean, unprintedglass, but with any gap between the surface and the printed side, the“frosted” appearance was noted, obscuring the object behind the glass tothe viewer while allowing most of the incident light to pass through theglass (as scattered rather than directly transmitted light).

The printed side of the glass was exposed to an etch solution of (i)0.1M HCl; (ii) 0.1N H₂SO₄; (iii) 4% acetic acid and (iv) 10% citricacid, at ambient temperature for a period of 15 minutes. After cleaningthe glass, no sign of the exposure to etch solution was evident.

In addition, the ink was printed on glass in a pattern of 10 mm-sizedspots with a glass surface coverage of 40%. Spots with “spider web”textures were printed. The PTV of wet glass is around 10, and of wetglass printed with similar patterns of standard it (Dip-Tech black ink)is 12. The PTV of the wet samples (average of three samples measurementsaccording to ASTM E303 Standard) were measured to be 70, i.e. exceedingeven the most strict specifications for industrial anti-slip surfaces.

Conclusions:

-   -   i) The combination of a suitable alumina dispersion and an        appropriate frit in the right ratio give an excellent        etch-effect coating.    -   ii) The use of appropriate frit results in an anti-slip or        etch-effect with high acid resistance.    -   iii) The combination of a suitable alumina dispersion and an        appropriate frit in the right ratio, together with an optimized        printed texture, gives an excellent anti-slip surface.

The glass panel and the method of revealing a hidden image could be usedin curtain walls, floors, in shower areas and kitchen back splashes. Thesecond image could be a standard and well accepted image of polka dotsor line patterns, or could be a pleasing, artistic image. Image colorselection is almost unlimited since the printing is conducted by, forexample, standard Cyan, Magenta, Yellow, White, and Black color inks.The hidden image is revealed when the second image printed on the firstsurface of the glass panel becomes covered by a transparent fluid. Thefluid could be applied intentionally, in course of the cleaning processor occasionally, when it is spilled in a kitchen or the shower areabecomes wet or when it rains.

FIG. 6 is a simplified illustration of decorative glass panel coveredfloor or a walk side with improved slip-resistance and revealed imageaccording to an example. The decorative glass floor or walk side 600with improved slip-resistance includes an assembly of generallytransparent glass panels (tiles) 608, similar to panels (tiles) 100 or400 or 500 with each panel/sheet including a first image printed on oneof the surfaces of the glass panel/sheet and a second image printed onthe same surface of the glass sheet and at least partially overlappingthe first image. As explained above, the second image is printed over atleast a segment of the first image and forms a partially opaque or anopaque imbedded into the glass sheet image with a high frictioncoefficient improving the slip-resistance of the glass panel (tile).

The walk side is surrounded on both sides by greenery 604 schematicallyshown as trees. When the greenery is irrigated or a rain falls down, thewater makes the second image printed on the glass panels transparent anddevelops/reveals the first, hidden image, which is a warning that theside walk has become slippery could be observed.

Roofing of residential and office buildings by the disclosed glasspanels could be another environmentally friendly application. FIG. 7 isa simplified illustration of a building 700 with a roof 704 covered bythe present glass panels. The ink printed on the outside (first surface)of the glass panels will be nominally opaque in sunny weather, providingrelief from excessive sunlight and heat. In rainy weather the roof 708(FIG. 7B) will become more transparent, allowing a greater proportion oflight to enter through the roof just when it is needed. In sunny dayssuch a roof saves electricity by reducing the air conditioning costs andin rainy days, it reduces the amount of electricity required to provideadequate illumination for work or living. In such applications only thesecond image needs to be printed on the outside (first) surface of theglass panel, although for aesthetic or decorative purposes, the firstimage that is obscured or revealed by the second image could be alsoprinted. The first image could be printed on the first (outer) surfaceof the glass panel or on the second (inner) surface of the glass panel.

Therefore, the disclosed glass panels provide environmentally friendly,fully recyclable construction material. The glass panels enhanceelectricity savings and provide a pleasing aesthetic appearance tointerior or exterior images.

The glass panels with slip-resistant developable image glass panel couldbe produced in different sizes and with different images. Thedevelopable image saves the need for warning signs and facilitatescleaning processes. The high friction non-slip surface reduces slip andfall accidents and reduces liability costs and insurance premiumsespecially for the operators of public spaces where the accidents tendto occur.

What is claimed is:
 1. An inkjet ink for printing a developable non-slipimage comprising: at least alumina dispersion and bismuth-based glassfrit, wherein a refractive index of the alumina is selected to be closeto the refractive index of the bismuth-based glass frit, and whereinalumina dispersion content is at least 21%.
 2. The ink according toclaim 1, wherein the bismuth-based glass frit content varies from 40% to60%.
 3. The ink according to claim 1, further comprising a solvent andwherein the solvent is a mixture of Dowanol DB and Cyclohexanone.
 4. Theink according to claim 1, further comprising a pigment, a binder, adispersant, and a surface tension reducer.